In this video lecture, Prof. David Attwood lectures on Van Cittert-Zernike, Coherence Experiments with Undulators, Lasers and HHG.

1. Class Overview I
2. Class Overview II
3. Laser Wavelength Scaling
4. Interaction Physics
5. Radiation by an Accelerated Charge
6. Scattering by Free and Bound Electron
7. X-ray Refractive Index
8. Brewster's angle and Multilayer mirrors
9. Multilayer Applications
10. Synchrotron Radiation
11. Bending Magnet Radiation
12. Undulator Radiation
13. Undulator Brightness and Harmonics
14. Plasma Physics
15. Plasma Physics (cont.)
16. Plasma Waves
17. Blackbody Radiation
18. High Harmonic Generation
19. Lasers
20. EUV and Soft x-ray Lasers
21. Coherence, Spatial and Temporal
22. Coherent Undulator Radiation
23. Van Cittert-Zernike Theorem
24. Zone Plate Formulas
25. Zone Plate Imaging and Microscopy
26. Spatial Resolution and Depth of Field
27. Applications of Zone Plate Microscopy
28. EUV lithography

In this course, Professor David Attwood gives 28 video lectures on Soft X-rays and Extreme Ultraviolet Radiation. Some of the topics covered in these video lectures are: Basic Absorption and Emission Processes; Scattering, Diffraction, and Refraction of Electromagnetic Radiation; Maxwell's Equations and the Wave Equation; Scattering by a Free Electron, Bound Electrons and Multi-Electron Atom; Brewster's Angle; Transition from Undulator to Wiggler Radiation; Hot Dense Plasmas and Synchrotron Radiation, Wiggler Power and Flux; Density Gradients, UV and EUV Probing; High Harmonic Generation with Femtosecond Laser Pulses; Recombination Lasing with Hydrogen-Like Carbon Ions; Collisionally Pumped Neon-Like Lasers; Coherence at Short Wavelengths; Spatial and Spectral Filtering of Undulator Radiation; X-Ray Microscopy with Diffractive Optics; Diffraction of Radiation by Pinhole Apertures and Zone Plates; High Resolution Soft X-Ray Microscopy; X-Ray Proximity Lithography, and many more.